大层厚下选区激光熔化成形316L不锈钢工艺的优化
Process Optimization of Selective Laser Melting Formed 316L Stainless Steel under Large Layer Thickness
摘 要
在铺粉厚度为0.15 mm的大层厚条件下采用选区激光熔化技术制备316L不锈钢试样,研究了激光功率(750~850 W)、扫描速度(800~1 000 mm·s-1)、扫描间距(0.06~0.10 mm)对其相对密度、显微组织与性能的影响,对选区激光熔化工艺进行了优化。结果表明:随着激光功率、扫描速度或扫描间距的增大,大层厚下成形试样的相对密度都呈先增大再减小的变化趋势。当激光功率为800 W、扫描速度为900 mm·s-1、扫描间距为0.08 mm时,成形试样的拉伸性能最优,其抗拉强度和断后伸长率分别为682.7 MPa和33.4%,与小层厚成形试样相近,此时的显微硬度为224.77 HV,显微组织由尺寸为0.4~1.0 μm的等轴晶组成,在质量分数3.5% NaCl溶液中的自腐蚀电位达到-0.69 V,表现出最优的耐腐蚀性能。
316L不锈钢
工艺参数
相对密度
大层厚
selective laser melting
316L stainless steel
process parameter
relative density
large layer thickness
Abstract
316L stainless steel samples were prepared by selective laser melting under the condition of large layer thickness with powder thickness of 0.15 mm. The effects of laser power (750-850 W), scanning speed (800-1 000 mm·s-1) and scanning spacing (0.06-0.10 mm) on the relative density, microstructure and properties of 316L stainless steel were studied, and the selective laser melting process was optimized. The results show that with the increase of laser power, scanning speed or scanning spacing, the relative density of the formed samples with large layer thickness all increased first and then decreased. When the laser power was 800 W, the scanning speed was 900 mm · s-1, and the scanning spacing was 0.08 mm, the tensile properties of the formed sample were the best, and the tensile strength and the percentage elongation after fracture were 682.7 MPa and 33.4%, respectively, which were close to those of the small layer thickness formed sample. Meanwhile, the microhardness was 224.77 HV, and the microstructure was composed of equiaxed grains with size of 0.4-1.0 μm; the free-corrosion potential in 3.5wt% NaCl solution reached -0.69 V, showing the best corrosion resistance.
中图分类号 TN249 DOI 10.11973/jxgccl202311017
所属栏目 专题报道(增材制造)
基金项目 安徽省新时代育人质量工程项目(2022zyxwjxalk084)
收稿日期 2023/4/29
修改稿日期 2023/10/16
网络出版日期
作者单位点击查看
备注夏涛(1998-),男,安徽六安人,硕士研究生
引用该论文: XIA Tao,HU Haixia. Process Optimization of Selective Laser Melting Formed 316L Stainless Steel under Large Layer Thickness[J]. Materials for mechancial engineering, 2023, 47(11): 104~110
夏涛,胡海霞. 大层厚下选区激光熔化成形316L不锈钢工艺的优化[J]. 机械工程材料, 2023, 47(11): 104~110
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参考文献
【1】卢秉恒,李涤尘.增材制造(3D打印)技术发展[J].机械制造与自动化,2013,42(4):1-4. LU B H,LI D C.Development of the additive manufacturing (3D printing) technology[J].Machine Building & Automation,2013,42(4):1-4.
【2】杨强,鲁中良,黄福享,等.激光增材制造技术的研究现状及发展趋势[J].航空制造技术,2016,59(12):26-31. YANG Q,LU Z L,HUANG F X,et al.Research status and development trend of laser additive manufacturing technology[J].Aeronautical Manufacturing Technology,2016,59(12):26-31.
【3】张学军,唐思熠,肇恒跃,等.3D打印技术研究现状和关键技术[J].材料工程,2016,44(2):122-128. ZHANG X J,TANG S Y,ZHAO H Y,et al.Research status and key technologies of 3D printing[J].Journal of Materials Engineering,2016,44(2):122-128.
【4】ALMANGOUR B A.Additive manufacturing of high-performance 316L stainless steel nanocomposites via selective laser melting[D].Los Angeles:UCLA,2017.
【5】HITZLER L,HIRSCH J,HEINE B,et al.On the anisotropic mechanical properties of selective laser-melted stainles steel[J].Materials,2017,10(10):1136.
【6】HONG Y J,ZHOU C S,ZHENG Y Y,et al.The cellular boundary with high density of dislocations governed the strengthening mechanism in selective laser melted 316L stainless steel[J].Materials Science and Engineering:A,2021,799:140279.
【7】苏正夫.铁粉激光直接成形温度场数值模拟[J].矿冶工程,2013,33(6):103-106. SU Z F.Numerical simulation of temperature field for laser direct forming of iron power[J].Mining and Metallurgical Engineering,2013,33(6):103-106.
【8】CHERRY J A,DAVIES H M,MEHMOOD S,et al.Investigation into the effect of process parameters on microstructural and physical properties of 316L stainless steel parts by selective laser melting[J].The International Journal of Advanced Manufacturing Technology,2015,76(5):869-879.
【9】MA M,WANG Z,GAO M,et al.Layer thickness dependence of performance in high-power selective laser melting of 1Cr18Ni9Ti stainless steel[J].Journal of Materials Processing Technology,2015,215(1):142-150.
【10】SUN Z,TAN X,SHU B T,et al.Selective laser melting of stainless steel 316L with low porosity and high build rates[J].Materials & Design,2016,104:197-204.
【11】BI J,LEI Z L,CHEN Y,et al.Effect of process parameters on formability and surface quality of selective laser melted Al-Zn-Sc-Zr alloy from single track to block specimen[J].Optics & Laser Technology,2019,118:132-139.
【12】GRAY G T,LIVESCU V,RIGG P A,et al.Structure/property (constitutive and spallation response) of additively manufactured 316L stainless steel[J].Acta Materialia,2017,138:140-149.
【13】尹燕,刘鹏宇,路超,等.选区激光熔化成形316L不锈钢微观组织及拉伸性能分析[J].焊接学报,2018,39(8):77-81. YIN Y,LIU P Y,LU C,et al. Microstructure and tensile properties of selective laser melting forming 316L stainless steel[J].Transactions of the China Welding Institution,2018,39(8):77-81.
【14】DE TERRIS T, ANDEREAU O,PEYRE P,et al.Optimization and comparison of porosity rate measurement methods of selective laser melted metallic parts[J].Additive Manufacturing,2019,28:802-813.
【15】DEBROY T,WEI H L,ZUBACK J S,et al.Additive manufacturing of metallic components:Process,structure and properties[J].Progress in Materials Science,2018,92:112-224.
【16】TOMASZ K,KONRAD G,WOJCIECH S,et al.Correlation between process parameters,microstructure and properties of 316L stainless steel processed by selective laser melting[J].Materials Science and Engineering:A,2018,718:64-73.
【17】张飞飞,刘玉德,石文天,等.选区激光熔化不同层厚316L不锈钢的微观形貌及性能[J].铸造技术,2018,39(12):2707-2711. ZHANG F F,LIU Y D,SHI W T,et al.Study on microstructure and properties of 316L with different thickness by selective laser melting[J].Foundry Technology,2018,39(12):2707-2711.
【18】王硕,刘玉德,祁斌,等.选区激光熔化316L大层厚成形工艺及性能研究[J].应用激光,2017,37(6):801-807. WANG S,LIU Y D,QI B,et al.Study on the forming process and performance of 316L high layer thickness by selective laser melting[J].Applied Laser,2017,37(6):801-807.
【19】SURYAWANSHI J,PRASHANTH K G, RAMAMURTY U.Mechanical behavior of selective laser melted 316L stainless steel[J].Materials Science and Engineering:A,2017,696:113-121.
【20】ZHANG B,DEMBINSKI L,CODDET C.The study of the laser parameters and environment variables effect on mechanical properties of high compact parts elaborated by selective laser melting 316L powder[J].Materials Science and Engineering:A,2013,584:21-31.
【2】杨强,鲁中良,黄福享,等.激光增材制造技术的研究现状及发展趋势[J].航空制造技术,2016,59(12):26-31. YANG Q,LU Z L,HUANG F X,et al.Research status and development trend of laser additive manufacturing technology[J].Aeronautical Manufacturing Technology,2016,59(12):26-31.
【3】张学军,唐思熠,肇恒跃,等.3D打印技术研究现状和关键技术[J].材料工程,2016,44(2):122-128. ZHANG X J,TANG S Y,ZHAO H Y,et al.Research status and key technologies of 3D printing[J].Journal of Materials Engineering,2016,44(2):122-128.
【4】ALMANGOUR B A.Additive manufacturing of high-performance 316L stainless steel nanocomposites via selective laser melting[D].Los Angeles:UCLA,2017.
【5】HITZLER L,HIRSCH J,HEINE B,et al.On the anisotropic mechanical properties of selective laser-melted stainles steel[J].Materials,2017,10(10):1136.
【6】HONG Y J,ZHOU C S,ZHENG Y Y,et al.The cellular boundary with high density of dislocations governed the strengthening mechanism in selective laser melted 316L stainless steel[J].Materials Science and Engineering:A,2021,799:140279.
【7】苏正夫.铁粉激光直接成形温度场数值模拟[J].矿冶工程,2013,33(6):103-106. SU Z F.Numerical simulation of temperature field for laser direct forming of iron power[J].Mining and Metallurgical Engineering,2013,33(6):103-106.
【8】CHERRY J A,DAVIES H M,MEHMOOD S,et al.Investigation into the effect of process parameters on microstructural and physical properties of 316L stainless steel parts by selective laser melting[J].The International Journal of Advanced Manufacturing Technology,2015,76(5):869-879.
【9】MA M,WANG Z,GAO M,et al.Layer thickness dependence of performance in high-power selective laser melting of 1Cr18Ni9Ti stainless steel[J].Journal of Materials Processing Technology,2015,215(1):142-150.
【10】SUN Z,TAN X,SHU B T,et al.Selective laser melting of stainless steel 316L with low porosity and high build rates[J].Materials & Design,2016,104:197-204.
【11】BI J,LEI Z L,CHEN Y,et al.Effect of process parameters on formability and surface quality of selective laser melted Al-Zn-Sc-Zr alloy from single track to block specimen[J].Optics & Laser Technology,2019,118:132-139.
【12】GRAY G T,LIVESCU V,RIGG P A,et al.Structure/property (constitutive and spallation response) of additively manufactured 316L stainless steel[J].Acta Materialia,2017,138:140-149.
【13】尹燕,刘鹏宇,路超,等.选区激光熔化成形316L不锈钢微观组织及拉伸性能分析[J].焊接学报,2018,39(8):77-81. YIN Y,LIU P Y,LU C,et al. Microstructure and tensile properties of selective laser melting forming 316L stainless steel[J].Transactions of the China Welding Institution,2018,39(8):77-81.
【14】DE TERRIS T, ANDEREAU O,PEYRE P,et al.Optimization and comparison of porosity rate measurement methods of selective laser melted metallic parts[J].Additive Manufacturing,2019,28:802-813.
【15】DEBROY T,WEI H L,ZUBACK J S,et al.Additive manufacturing of metallic components:Process,structure and properties[J].Progress in Materials Science,2018,92:112-224.
【16】TOMASZ K,KONRAD G,WOJCIECH S,et al.Correlation between process parameters,microstructure and properties of 316L stainless steel processed by selective laser melting[J].Materials Science and Engineering:A,2018,718:64-73.
【17】张飞飞,刘玉德,石文天,等.选区激光熔化不同层厚316L不锈钢的微观形貌及性能[J].铸造技术,2018,39(12):2707-2711. ZHANG F F,LIU Y D,SHI W T,et al.Study on microstructure and properties of 316L with different thickness by selective laser melting[J].Foundry Technology,2018,39(12):2707-2711.
【18】王硕,刘玉德,祁斌,等.选区激光熔化316L大层厚成形工艺及性能研究[J].应用激光,2017,37(6):801-807. WANG S,LIU Y D,QI B,et al.Study on the forming process and performance of 316L high layer thickness by selective laser melting[J].Applied Laser,2017,37(6):801-807.
【19】SURYAWANSHI J,PRASHANTH K G, RAMAMURTY U.Mechanical behavior of selective laser melted 316L stainless steel[J].Materials Science and Engineering:A,2017,696:113-121.
【20】ZHANG B,DEMBINSKI L,CODDET C.The study of the laser parameters and environment variables effect on mechanical properties of high compact parts elaborated by selective laser melting 316L powder[J].Materials Science and Engineering:A,2013,584:21-31.
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